参考文献
[1]European Directive 94/67 on Incineration of Hazardous Wastes[S].1994.
[2]Marani D,Braguglia C M.Behavior of Cd,Cr,Mn,Ni,Pb,and Zn in sewage sludge incineration by fluidized bed furnace[J].Waste Management,2003,23(2):117-124.
[3]Hartman M,Pohorely M.Behavior of Inorganic Constituents of Municipal Sewage Sludge during Fluidized-Bed Combustion[J].Chemical Papers,2007,61(3):181-185.
[4]Lena A E,Amand L.The fate of trace elements in fluidized bed combustion of sewage sludge and wood[J].Fuel,2007,86(1):834-852.
[5]李季,杨学民,林伟刚.城市生活垃圾焚烧体系化学热力学平衡分析[J].燃料化学学报,2003(06):584-588.
[6]Abanades S,Flamant G,Gagnepain B,et al.Fate of heavy metals during municipal solid waste incineration[J].Waste Management&Research,2002,20(2):55-68.
[7]陈勇,张衍国,李清海等.垃圾焚烧中氯化物对重金属Pb迁移转化特性的影响[J].燃料化学学报,2008,36(3):354-359.
[8]李国建,胡艳军,陈冠益等.城市污水污泥与固体垃圾混烧过程中重金属迁移特性的研究[J].燃料化学学报,2011,39(2):155-160.
[9]孙路石,陆继东,张娟.城市垃圾焚烧过程中重金属释放行为的试验研究[J].燃烧科学与技术,2003,9(6):516-520.
[10]胡建杭,王华,吴桢芬等.垃圾焚烧过程重金属的氯化转化与挥发[J].材料与冶金学报,2008,7(1):69-74.
[11]Wang K S,Chiang K Y.Effects of Chlorides on Emissions of Toxic Compounds in Waste Incineration:Study on Partitioning Characteristics of Heavy Metal[J].Chemosphere,1999,38(8):1833-1849.
[12]Toledo J M,Corella J,Corella LM.The partitioning of heavy metals in incineration of sludge and waste in a bubbling fluidized bed[J].Journal of Hazardous Materials,2005,126(B):158-168.
[13]环境保护部.固体废物浸出毒性浸出方法水平振荡法[S].北京:中国环境科学出版社,2010.
[14]王涛,刘廷凤,高占啟,孙成.城市垃圾焚烧飞灰的污染特性分析[J].南京大学学报(自然科学版),2008,41(1).
[15]中国标准出版社第二编辑室.中国环境保护标准汇编(环境质量与污染物排放2003)[M].北京:中国标准出版社,2003.
[16]Netherlands Norm of sampling,NEN-EN-932-1[S].Netherlands,1996.
[17]VanGrieken R E,Markowicz A A,Handbook of X-Ray Spectrometry[M].New York:Marcel Dekker,1993.
[18]European Norm,EN7432/2:Standard leaching methods of aggregate materials[S].European Union,1999.
[19]European Norm,European EN 1097-6:Standard measurement of densities of aggregate materials[S].European Union,2013.
[20]ASTM D4318-05:Standard Test Methods for Liquid Limit,Plastic Limit,and Plasticity Index of Soils[S].2003.
[21]European standard,EN 1097-6:2000/A1:2005,Tests for mechanical and physical properties of aggregates—Part 6:Determination of particle density and water absorption[S].European Union,2000/2005.
[22]Technical Norm NLT 111.1987,Geotechnical Laboratory Cedex.Ministry of Foment[S].Spain,1987.
[23]Technical Norm NLT 149.1991,Geotechnical Laboratory Cedex.Ministry of Foment[S].Spain,1991.
[24]Technical Norm NLT 108.1991,Geotechnical Laboratory Cedex.Ministry of Foment[S].Spain,1991.
[25]ASTM C1260-07.Standard Test Method for Potential Alkali Reactivity of Aggregates[S].U.S.,2003.
[26]Soler L,Macansas M,Casado J,Aluminum and aluminum alloys as source of hydrogen for fuel cell applications[J].Journal of Power Sources,2007,169(1):144-149.
[27]Das S.K.,Secat,Inc.Designing aluminum alloys for a Recycle-Friendly World[J].Light Metal Age,2006,519-521(6):1239-1244.
[28]Das S K,Kaufman G J.Recycling aluminum aerospace alloys[J].Light Metals,2007:1161-1165.
[29]Muchova L,Rem P.Pilot plant for wet physical separation of MSWI bottom ash[C].Conference proceeding MMME,Cape Town(South Africa),14-15 November,2006.
[30]Gy P M.Sampling of particulate materials:theory and practice[M].Amsterdam:Elsevier Science Pub.co.,1982.